Wireless Frequency-Domain Multi-Channel Communications

1. A circuit comprising: a digital modulation circuit receiving multiple channel binary data, and for each channel generating a digital representation; a digital-to-analogue (D/A) conversion circuit for each data channel, each said D/A conversion circuit receiving and converting respective said channel digital representations at a sampling rate to produce a resultant analogue signal that is band limited within each Nyquist zone of the sampling rate of said D/A conversion circuit, said band limitation being dependent on a characteristic of said channel digital representations; a bandpass filter receiving and filtering each analogue signal, the band width at the edges of the stop band of each said bandpass filter being wider than a respective band limited analogue signal and wider than the Nyquist bandwidth arising from the sampling rate of said D/A conversion circuit, whereby signal power in unwanted Nyquist zones is effectively removed; and a frequency translation circuit for translating said multiple channel bandpass filtered analogue signals in the frequency domain such that said multiple channel bandpass filtered analogue signals are each offset in the frequency domain by the band limitation of the band limited analogue signal, thereby abutting said multiple channel bandpass filtered analogue signals without any guard bands between adjacent channel signals.

2. A circuit according to claim 1 , wherein said digital modulation circuit converts one of more channel binary data values to a symbol value, and generates a summed time sequence of digital data values implementing constituent impulse responses for each said symbol value.

3. A circuit according to claim 1 , wherein said characteristic of said digital representations is a symbol rate and a parameter α.

4. A circuit according to claim 2 , wherein said digital modulation circuit includes a memory storing said digital data values implementing said impulse responses that correspond to said symbol values.

5. A circuit according to claim 2 , wherein said symbols are at least 3 bits in length.

6. A circuit according to claim 2 , wherein said digital modulation circuit implements a Raised Root Cosine filter to generate said time sequences.

7. A circuit according to claim 1 , wherein said digital modulation circuit implements any one of 8 value phase shift keying (8-PSK), or 16 or 64 value quadrature amplitude modulation.

8. A circuit according to claim 1 , wherein said band limited analogue channel signal occupies no more than 40% of the total bandpass filter width as measured to the edge of the stop bands.

9. A circuit according to claim 1 , further comprising a digital demultiplexer circuit, demultiplexing input binary data into said multiple channel binary data.

10. A circuit according to claim 1 , wherein there are at least 4 said channels.

11. A circuit according to claim 1 , further comprising a radio frequency circuit to combine said abutted channel signals and transmit said combine signals at radio frequencies.

12. A method for transmitting data comprising: forming a limited duration digital representation of multiple input data channels; converting each said digital representation to an analogue signal at a sampling rate, wherein the analogue signal is band limited within each Nyquist zone of the sampling rate for each channel; bandpass filtering each analogue signal for each channel, wherein the band width at the edges of the stop band of each said bandpass filter being wider than a respective band limited analogue signal and wider than the Nyquist bandwidth arising from the sampling rate of said conversion, whereby signal power in unwanted Nyquist zones is effectively removed; translating said bandpass filtered analogue signals in the frequency domain such that said bandpass filtered analogue signals are each offset in the frequency domain by the band limitation of the band limited analogue signal, thereby abutting said multiple channel bandpass filtered analogue signals without any guard bands; and wirelessly transmitting said abutted bandpass filtered analogue signals.

13. A transceiver comprising: (a) a transmitter circuit including: a digital modulation circuit receiving multiple channel binary data, and for each channel generating a digital representation; a digital-to-analogue (D/A) conversion circuit for each data channel, each said D/A conversion circuit receiving and converting respective said channel digital representations at a sampling rate to produce a resultant analogue signal that is band limited within each Nyquist zone of the sampling rate of said D/A conversion circuit, said band limitation being dependent on a characteristic of said channel digital representations; a bandpass filter receiving and filtering each analogue signal, the band width at the edges of the stop band of each said bandpass filter being wider than a respective band limited analogue signal and wider than the Nyquist bandwidth arising from the sampling rate of said D/A conversion circuit, whereby signal power in unwanted Nyquist zones is effectively removed; and a frequency translation circuit for translating said multiple channel bandpass filtered analogue signals in the frequency domain such that said multiple channel bandpass filtered analogue signals are each offset in the frequency domain by the band limitation of the band limited analogue signal, thereby abutting said multiple channel bandpass filtered analogue signals without any guard bands between adjacent channel signals; and (b) a receiver circuit including: a radio frequency circuit to receive a multiple channel radio frequency signal, said multiple channels being abutted; a frequency translation circuit for separating said received multiple channel signals by frequency translation; an analogue-to-digital (A/D) conversion circuit for each channel, each said A/D conversion circuit converting a respective analogue channel signal to a digital representation; and a digital demodulation circuit receiving said channel signal digital representation and generating channel symbols therefrom, and generating multiple channel binary data from said symbols.

14. A transceiver according to claim 13 , wherein said receiver further includes a bandpass filter for each separate channel signal to filter said channel signals before passing the signals to the respective A/D conversion circuit.

15. A transceiver according to claim 13 , wherein said demodulation circuit includes a filter component matching channel signals in the modulation circuit of the transmitter circuit.

16. A transceiver according to claim 13 , wherein said transmitter circuit further includes a digital demultiplexer, demultiplexing input binary data into said multiple channel binary data; and said receiver circuit further includes a digital multiplexer, multiplexing said binary channel data in to a single output data stream.